Solid drill bit for machine tools

ABSTRACT

The invention relates to a solid drill bit for machine tools. Said first bit has a bit body ( 10 ) and two movable inserts ( 20,22 ) which are located a radial distance apart, each in an insert seat ( 16,18 ) of the bit body ( 10 ), in the area of a chip-conveying channel ( 12,14 ). The moveable inserts ( 20,22 ) have a rectangular or quadratic contour, project axially over the bit body ( 10 ) with their front-end main blades ( 30,34 ) and overlap each other radially in their working area. The radially outer movable insert ( 22 ) projects radially beyond the periphery of the bit body ( 10 ) with its outer tool corner ( 36 ) and with its adjoining secondary blade ( 38 ), which is perpendicular to the corresponding main blade ( 34 ). Starting from the tool corner ( 36 ), the longitudinal extension of the secondary blade ( 38 ) concerned is inclined in the direction of the bit body ( 10 ) at a defined setting angle of less than 3.2°. The secondary blade ( 38 ) has a guiding edge ( 44 ), with which it is slidingly supported against the wall ( 42 ) of the bore that is produced during the drilling process, at least over part of its length and under the influence of a radially outwardly oriented thrust force.

DESCRIPTION

[0001] The invention relates to a boring tool for machine tools for drilling into solid material having a bit body and at least two movable inserts rectangular or square in contour arranged at a radial distance from one another and in a recess of the bit body in the area of a chip-conveying channel, project, with their front facing end major cutting edges axially beyond the bit body and radially overlap one another in their working area, whereby the radially outer movable insert projects radially beyond the periphery of the bit body with its outer rounded cutting edge corner and with its following minor cutting edge, which is perpendicular to the respective major cutting edge, and whereby the minor cutting edge is tilted starting out from the cutting edge corner in its longitudinal extent at a defined setting angle in direction of the bit body.

[0002] Boring tools of this type having two square movable inserts are known (DE-A-2843788). The two square inserts are arranged at different radial distances from one another. They project with their front facing end major cutting edges with a positive face angle axially beyond the bit body. They furthermore have in direction of rotation an angle different than 180°, whereby the inner insert runs there ahead of the outer insert in direction of rotation. The inner insert is pre-cut in axial direction, whereby the spacing corresponds approximately with the radius of curvature in the area of the cutting edge corners. The major cutting edge of the innermost insert does not project beyond the drill-bit axis. The inclination of the minor cutting edge of the outermost insert is chosen such that it rubs on the wall of the bore. In order to avoid frictional actions, the setting angle of the minor cutting edge is chosen to be at least 5°. The corresponding setting angle of the inserts, which are farther on the inside, is yet slightly greater, namely with the goal that an even load distribution occurs on the movable inserts.

[0003] The purpose of the invention is to improve the known solid drill bits of the above-disclosed type so that an increased exactness with at least the same metal-removing performance is achieved.

[0004] To attain this purpose the characteristic combinations disclosed in claims 1 and 4 are suggested. Advantageous embodiments and further developments of the invention result from the dependent claims.

[0005] The inventive solution is primarily based on the thought that the minor cutting edge forms a guiding edge, which rests slidingly during the drilling operation under the action of a radially outwardly directed thrust force at least over a part of its length against the wall of the earlier created bore. In order to achieve this, it is suggested according to the invention that the setting angle of the minor cutting edge is smaller than 3.2°, preferably 1.2° to 2.2°. The minor cutting edge advantageously rests slidingly over more than 20%, preferably 30% to 60% of the length of its guiding edge against the wall of the bore. Most of all, in the case of the smallest possible setting angle, it is achieved at a given modulus of elasticity of the workpiece material that the minor cutting edge rests slidingly over the entire length of its guiding edge against the wall of the bore. The limit of the setting angle is achieved when a chip-removing frictional action occurs in the area of the minor cutting edge.

[0006] Since the minor cutting edge of a movable insert can through movement become a major cutting edge, particular attention must be paid that no wear occurs in the direct vicinity of the cutting edge. This can be avoided by forming the guiding edge through a land of the flank or curvature of the minor cutting edge. As an alternative, it is also possible to form the guiding edge through a face land or curvature of the minor cutting edge. The correct positioning of the movable insert in the tool can be recognized since during the drilling operation indeed in the area of the land of the flank or face land a material smoothing takes place at least over a part of the minor cutting edge length, not, however, in the direct area of the minor cutting edge. This phenomenon is a sign that the minor cutting edge rests slidingly with a partially elastic deformation and, if necessary, with a smoothing of unevennesses against the wall of the bore.

[0007] A further improvement in this respect is achieved when the movable inserts carry at least in the area of their major and minor cutting edges a friction-reducing, wear-resistant coat. The coat can consist, for example, of a material of the group titanium nitride, titanium carbonitride, aluminum nitride or aluminum oxide.

[0008] An advantageous development of the invention provides that the inner insert projects with its inner rounded cutting edge corner over the drill-bit axis. It is achieved with this measure that in the area of the inner and of the outer movable inserts chip chambers of approximately the same size are created, which chambers enlarge starting from the major cutting edge. It is assured in this manner that the relatively wide chips created during the drilling operation can be discharged through the chip-conveying channels without any danger of jamming.

[0009] The centering characteristics of the boring tool can be improved when the major cutting edge of the inner movable insert has a pre-cutting spacing from the major cutting edge of the outer movable insert, which is smaller than the corner radius, preferably smaller than 30% of the corner radius of the movable inserts. Expressed in absolute units of measurement, the pre-cutting spacing is less than 0.5 mm, preferably 0.15 to 0.3 mm.

[0010] To optimize the radially acting thrust forces, it is suggested according to a further advantageous development of the invention that the face angle of the major cutting edges of the inner movable insert is greater, preferably twice as large as the face angle of the outer movable insert.

[0011] To further optimize the radial thrust forces engaging the boring tool during the drilling operation, it is suggested according to a preferred development of the invention that the major cutting edge of the outer movable insert defines with the major cutting edge of the inner movable insert in direction of rotation about the drill-bit axis an angle which is smaller than 180°. It can in addition be achieved with this measure that in the area of the inner and of the outer movable inserts there exists an approximately equal cross-sectional opening of the chip-conveying channels.

[0012] The invention will be discussed in greater detail hereinafter in connection with one exemplary embodiment schematically illustrated in the drawings, in which:

[0013]FIG. 1 is a diagrammatic illustration of a solid drill bit for machine tools having square movable inserts;

[0014]FIG. 2a to 2 c are a top view and two sectional side views of the solid drill bit according to FIG. 1;

[0015]FIG. 3a is a fragmentary cross-sectional illustration of the minor cutting edge of the outer movable insert of the boring tool according to FIGS. 1 and 2 with a guiding edge in the area of a land of the flank;

[0016]FIGS. 3b and 3 c are each a fragment of FIG. 3a with a curvature and an additional land in the area of a flank of the minor cutting edge.

[0017] The tool illustrated in the drawings is designated as a solid drill bit for machine tools. It has an essentially cylindrical bit body 10 having two chip-conveying channels 12, 14. A recess 16, 18 is provided on the front facing end of each of the chip-conveying channels in order to receive a square movable insert 20, 22. Each of the movable inserts 20, 22 are fastened to the bit body 10 with a countersunk head screw 26 received in a taphole 24 in the bit body 10. As can be seen in FIGS. 2a to 2 c, the inner movable insert 22 extends with the inner rounded cutting edge corner 28 on its front facing end major cutting edge 30 over the drill-bit axis 32, whereas the outer movable insert 22 projects with its major cutting edge 34 in the area of the outer rounded cutting edge corner 36 and with its outer minor cutting edge 38 beyond the periphery of the bit body 10. The movable inserts with their major and minor cutting edges are furthermore arranged tilted with respect to the bit body 10 in such a manner that the major cutting edges define a positive angle α_(i)=4° or α_(a)=2° with respect to a plane that is perpendicular with respect to the drill-bit axis, whereby the indices i and a identify the inner or outer insert. Since the minor cutting edge 38 is aligned perpendicularly with respect to the respective major cutting edge 34, the minor cutting edge 38 is in the illustrated exemplary embodiment inclined, starting from the cutting edge corner 36, in its longitudinal extent with a setting angle in direction of the bit body, which angle corresponds with the angle α_(a). FIG. 2a shows furthermore that the major cutting edge 34 of the outer movable insert 22 defines with the major cutting edge 30 of the inner movable insert 20 in the direction of rotation indicated by the arrow 40 about the drill-bit axis 32 an angle which is less by an amount of the angle β than 180°. The angle β is approximately 5° in the illustrated exemplary embodiment. Finally FIG. 2b shows that the major cutting edge 30 of the inner movable insert 20 has a pre-cutting spacing d from the major cutting edge 34 of the outer movable insert 22, which is less than the corner radius of the major cutting edges, and which in the illustrated exemplary embodiment is 0.23 mm. The angles α_(i), α_(a) and β and the pre-cutting spacing d are chosen such that the drill bit rests slidingly with a defined radial thrust force in the area of its outer minor cutting edge 38 against the wall 42 of the created bore.

[0018] The minor cutting edge 38 has for this purpose a guiding edge 44, with which the outer movable insert 22 rests slidingly against the wall 42 of the bore. The guiding edge 44 is in the embodiment illustrated in FIG. 3b formed by a flank curvature of the minor cutting edge, whereas in the case of FIG. 3c it is formed by a land of the flank. The actual cutting edge of the minor cutting edge 38 is slightly shifted inwardly compared with the guiding edge 44 so that no wear in the direct vicinity of the minor cutting edge 38 occurs during the drilling operation. The guiding edge is merely smooth due to its sliding bearing against the wall of the bore. Due to the very small setting angle of the minor cutting edge 38 relative to the drill-bit axis 32, the minor cutting edge rests with its guiding edge 44 at least over a part of its length against the wall of the bore. The thrust forces are in this manner distributed over a larger surface so that metal removal does not occur in the area of the minor cutting edge but at most a smoothing of the wall of the bore. To improve the sliding action it is possible to provide the movable inserts with a friction-reducing coat, for example, of titanium nitride, titanium cabonitride, aluminum nitride or aluminum oxide.

[0019] The described arrangement of the movable inserts 20, 22 in the chip-conveying channels assures that a sufficient, slightly enlarging cross-sectional opening for the chips is formed, and that a strong base on the bit body 10 still remains for the movable inserts.

[0020] In summary, the following is to be stated: The invention relates to a solid drill bit for machine tools. The solid drill bit has a bit body 10 and two movable inserts 20, 22 each arranged at a radial distance from one another and in a respective insert seat 16, 18 of the bit body 10 in the area of a chip-conveying channel 12, 14. The movable inserts 20, 22 have a rectangular or square contour. Their front facing major cutting edges 30, 34 project axially beyond the bit body 10, and overlap one another radially in their working area. The radially outer movable insert 22 projects with its outer cutting edge corner 36 and with its following minor cutting edge 38, which is perpendicular to the respective major cutting edge 34, radially beyond the periphery of the bit body 10. The respective minor cutting edge 38 is furthermore inclined at a defined setting angle, which angle is less than 3.2°, starting out from the cutting edge corner 36 in its longitudinal extent in direction of the bit body 10. The minor cutting edge 38 has a guiding edge 44, with which it rests slidingly during the drilling operation under the action of a radially outwardly directed thrust force at least over a part of its length against the wall 42 of the created bore. 

1. A solid drill bit for machine tools with a bit body (10) and at least two movable inserts (20, 22), rectangular or square in contour, each arranged at a radial distance from one another and in a recess (16, 18) in the bit body (10) in the area of a chip-conveying channel (12, 14), project with their front facing end major cutting edges (30, 34) axially beyond the bit body (10), and radially overlap one another in their working area, whereby the radially outermost movable insert (22) projects radially beyond the periphery of the bit body (10) with its outer rounded cutting edge corner (36) and with its following minor cutting edge (38), which is perpendicular to the respective major cutting edge (34), and whereby the respective minor cutting edge (38) is inclined starting out from the cutting edge corner (36) in its longitudinal extent at a defined setting angle (α_(a)) in direction of the bit body, characterized in that the setting angle of the minor cutting edge (38) is less than 3.2°.
 2. The solid drill bit according to claim 1, characterized in that the setting angle (α_(a)) is 1.2° to 2.2°.
 3. The solid drill bit according to claim 1 or 2, characterized in that the minor cutting edge (38) forms a guiding edge (44) which rests slidingly during the drilling operation under the action of a radially outwardly directed thrust force at least over a part of its length against the wall (42) of the created bore.
 4. A solid drill bit for machine tools with a bit body (10) and at least two movable inserts (2, 22), rectangular or square in contour, each arranged at a radial distance from one another and in a recess (16, 18) of the bit body (10) in the area of a chip-conveying channel (12, 14), project with their front facing end major cutting edges (30, 24) axially beyond the bit body (10), and radially overlap one another in their working area, whereby the radially outermost movable insert (22) projects radially beyond the periphery of the bit body (10) with its outer rounded cutting edge corner (36) and with its following minor cutting edge (38), which is perpendicular to the respective major cutting edge (34), and whereby the respective minor cutting edge (38) is inclined starting out from the cutting edge corner (36) in its longitudinal extent at a defined setting angle (α_(a)) in direction of the bit body, characterized in that the minor cutting edge (38) forms a guiding edge (44) which rests slidingly during the drilling operation under the action of a radially outwardly directed thrust force at least over a part of its length against the wall (42) of the created bore.
 5. The solid drill bit according to claim 3 or 4, characterized in that the outer minor cutting edge (38) of the outermost movable insert (22) rests slidingly over more than 20% of the length of its guiding edge (44) against the wall (42) of the bore.
 6. The solid drill bit according to one of the claims 3 to 5, characterized in that the outer minor cutting edge (38) of the outermost movable insert (22) rests slidingly over 30% to 60% of the length of its guiding edge (44) against the wall (42) of the bore.
 7. The solid drill bit according to one of the claims 3 to 5, characterized in that the minor cutting edge (38) rests slidingly over the entire length of its guiding edge (44) against the wall (42) of the bore.
 8. The solid drill bit according to one of the claims 3 to 7, characterized in that the guiding edge (44) is formed by a land of the flank and/or curvature of the minor cutting edge.
 9. The solid drill bit according to one of the claims 3 to 7, characterized in that the guiding edge (44) is formed by a face land and/or curvature of the minor cutting edge.
 10. The solid drill bit according to one of the claims 3 to 9, characterized in that the outer minor cutting edge (38) of the outermost movable insert (22) rests slidingly against the wall (42) of the bore under a partial elastic deformation.
 11. The solid drill bit according to one of the claims 3 to 10, characterized in that the outer minor cutting edge (38) of the outermost movable insert (22) rests slidingly against the wall (42) of the bore while smoothing unevennesses.
 12. The solid drill bit according to one of the claims 1 to 11, characterized in that the innermost movable insert (20) extends with its major cutting edge (30) in the area of its inner rounded cutting edge corner (28) over the drill-bit axis (32).
 13. The solid drill bit according to one of the claims 1 to 8, characterized in that the major cutting edge (30) of the innermost movable insert (20) has a pre-cutting spacing (d) from the major cutting edge (34) of the outer movable insert (22), which is smaller than the corner radius of the major cutting edge.
 14. The solid drill bit according to claim 13, characterized in that the pre-cutting spacing (d) is less than 50% of the corner radius.
 15. The solid drill bit according to claim 13 or 14, characterized in that the pre-cutting spacing (d) is less than 0.5 mm, preferably 0.15 to 0.3 mm.
 16. The solid drill bit according to one of the claims 1 to 15, characterized in that the face angle (a_(i)) of the major cutting edge (30) of the innermost movable insert (20) is greater than the face angle (α_(a)) of the major cutting edge (34) of the outermost movable insert (22).
 17. The solid drill bit according to claim 16, characterized in that the face angle (α_(i)) of the major cutting edge (30) of the innermost movable insert (20) is twice as large as the face angle (α_(a)) of the major cutting edge (34) of the outermost movable insert (22).
 18. The solid drill bit according to one of the claims 1 to 17, characterized in that two movable inserts (20, 22) are provided, whereby the major cutting edge (34) of the outermost movable insert (22) defines with the major cutting edge (30) of the innermost movable insert (20) in direction of rotation (40) about the drill-bit axis (32) an angle which is smaller than 180°.
 19. The solid drill bit according to one of the claims 1 to 18, characterized in that the movable inserts (20, 22) carry at least in the area of their major and minor cutting edges a friction-reducing, wear-resistant coat.
 20. The solid drill bit according to claim 19, characterized in that the coat consists of a material of the group titanium nitride, titanium carbonitride, aluminum nitride, aluminum oxide. 